Super silicon: top semiconductor turns into a superconductor.While not yet leaping over tall buildings in a single bound, silicon is doing something pretty super these days--conducting electricity with zero resistance. The material achieved that triumph when physicists in France crammed unprecedented numbers of boron boron (bōr`ŏn) [New Gr. from borax], chemical element; symbol B; at. no. 5; at. wt. 10.81; m.p. about 2,300°C;; sublimation point about 2,550°C;; sp. gr. 2.3 at 25°C;; valence +3. atoms into a silicon wafer's surface. When cooled to less than 0.4 kelvin, the boron-laden silicon permitted electrons to flow unimpeded unimpeded Adjective not stopped or disrupted by anything Adj. 1. unimpeded - not slowed or prevented; "a time of unimpeded growth"; "an unimpeded sweep of meadows and hills afforded a peaceful setting" , the scientists report in the Nov. 23 Nature. As the stuff of microchips, "silicon has become the technologically most important material of the past 50 years," notes superconductivity superconductivity, abnormally high electrical conductivity of certain substances. The phenomenon was discovered in 1911 by Kamerlingh Onnes, who found that the resistance of mercury dropped suddenly to zero at a temperature of about 4.2°K;. researcher Robert J. Cava of Princeton University Princeton University, at Princeton, N.J.; coeducational; chartered 1746, opened 1747, rechartered 1748, called the College of New Jersey until 1896. Schools and Research Facilities in a commentary in the same journal issue. Silicon's characteristics as a semiconductor--a substance with electrical properties midway between those of a conductor and an insulator--make it the dominant material of microelectronics. In experiments in the 1980s, other teams fleetingly made silicon a superconductor A material that has little resistance to the flow of electricity. Traditional superconductors operate at absolute zero (-459.67 degrees Fahrenheit or -273.15 degrees Celsius). Experiments in the 1980s raised the temperature to -321 degrees Fahrenheit. when they squeezed it to about 100,000 times atmospheric pressure atmospheric pressure or barometric pressure Force per unit area exerted by the air above the surface of the Earth. Standard sea-level pressure, by definition, equals 1 atmosphere (atm), or 29.92 in. (760 mm) of mercury, 14.70 lbs per square in., or 101. . Cava calls the new, more lasting superconductor a "breakthrough." He adds, however, that "it's too early to tell [whether it's] a herald of more and better devices and materials:' Indeed, making silicon so profoundly cold would be commercially impractical, admits Etienne Bustarret of the National Center for Scientific Research in Grenoble, a member of the research team. However, he adds, it's possible that further modifications could boost the superconducting temperature. "This discovery suggests a possibility of producing new ... devices,' particularly if researchers could make a second silicon superconductor with phosphorus, comments Yoshihiko Takano of the National Institute for Materials Science materials science Study of the properties of solid materials and how those properties are determined by the material's composition and structure, both macroscopic and microscopic. in Tsukuba, Japan. The boron-and phosphorus-infused superconductors could be combined to form electronic components, he says. To make commercial transistors, manufacturers put atoms of boron, phosphorus, or other elements into silicon. Bustarret and his colleagues injected millions of times greater concentrations of boron into 10 spots on a silicon wafer. To do so, the team put the wafer in a chamber of boron chloride gas and blasted each spot with a powerful ultraviolet laser that emitted 200 bursts, each lasting 25 nanoseconds. Each pulse melted the silicon surface. Ultimately, boron atoms took more than 8 percent of crystal locations normally occupied by silicon atoms. Besides pursuing a phosphorus version of the silicon superconductor, Bustarret and his team are force-feeding elements to other semiconductors--such as aluminum nitride--that they expect to superconduct at higher temperatures. "The treatment they meted out Adj. 1. meted out - given out in portions apportioned, dealt out, doled out, parceled out distributed - spread out or scattered about or divided up to silicon to force its conversion," Cava quips, "can only be termed abusive." |
|
||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion